Circumferential magnetic Barkhausen noise distribution and plane stress measurement

被引：0

作者：

Zheng Y. ^{[1
]}

Zhang X. ^{[1
,2
]}

Zhou J. ^{[2
]}

Tan J. ^{[1
]}

机构：

[1] China Special Equipment Inspection and Research Institute, Beijing

[2] School of Mechanical Engineering, North University of China, Taiyuan

来源：

Zhou, Jinjie (zhoujinjiechina@126.com) | 1600年 / Science Press卷 / 42期

关键词：

Circumferential magnetic Barkhausen noise distribution; Nondestructive testing; Plane stress tensor; Principal stress; Stress measurement;

D O I：

10.19650/j.cnki.cjsi.J2107554

中图分类号：

学科分类号：

摘要：

Magnetic Barkhausen noise is sensitive to stress, which is an in-situ non-destructive stress measurement technology with convenient operation, high detection sensitivity and good repeatability. It has broad application prospect in residual stress measurement, stress concentration zone evaluation of parts and bearing stress evaluation of structures. The measurement of the maximum principal stress and its direction during the measurement of the plane stress on the surface of ferromagnetic materials in engineering is an urgent problem to be solved. Proposes a plane stress measurement method based on the circumferential magnetic Barkhausen noise distribution, and establishes the solution of the plane stress tensor. The model realizes the demodulation of normal stress and shear stress in any direction of the measuring point. Experiments have verified the effectiveness of this method. Measurement results show that when the principal stress is greater than 50 MPa, the measured maximum principal stress direction deviation is 10°, the maximum normal stress deviation is 5 MPa and the maximum shear stress deviation is 6 MPa, which has high measurement accuracy. © 2021, Science Press. All right reserved.

引用

页码：75 / 87

页数：12

共 22 条

[11] HE C F, CAI Y CH, LIU X CH, Et al., Comparative of models for quantitative prediction of surface hardness in S136 steel based on magnetic barkhausen noise, Journal of Mechanical Engineering, 55, 18, pp. 15-21, (2019)
[12] SOULTAN M, KLEBER X, CHICOIS J., Mechanical Barkhausen noise during fatigue of iron, Ndt & E International, 39, 6, pp. 493-498, (2006)
[13] VINCENT A, PASCO L, MORIN M, Et al., Magnetic Barkhausen noise from strain-induced martensite during low cycle fatigue of 304L austenitic stainless steel, Acta Materialia, 53, 17, pp. 4579-4591, (2005)
[14] DING S, TIAN G Y, DOBMANN G, Et al., Analysis of domain wall dynamics based on skewness of magnetic Barkhausen noise for applied stress determination, Journal of Magnetism and Magnetic Materials, 421, pp. 225-229, (2017)
[15] KYPRIS O, NLEBEDIM I C, JILES D C., A new method for obtaining stress-depth calibration profiles for non-destructive evaluation using a frequency-dependent model of barkhausen emissions, IEEE Transactions on Magnetics, 49, 7, pp. 3893-3896, (2013)
[16] SAMIMI A A, KRAUSE T W, CLAPHAM L., Stress response of magnetic barkhausen noise in submarine hull steel: A comparative study, Journal of Nondestructive Evaluation, 35, 2, (2016)
[17] GRIJALBA F A F, PADOVESE L R., Non-destructive scanning for applied stress by the continuous magnetic Barkhausen noise method, Journal of Magnetism and Magnetic Materials, 466, pp. 231-238, (2018)
[18] HAUSILD P, KOLARIK K, KARLIK M., Characterization of strain-induced martensitic transformation in A301 stainless steel by Barkhausen noise measurement, Materials & Design, 44, pp. 548-554, (2013)
[19] VENGRINOVICH V, VINTOV D, PRUDNIKOV A, Et al., Magnetic Barkhausen effect in steel under biaxial strain/stress: Influence on stress measurement, Journal of Nondestructive Evaluation, 38, 2, (2019)
[20] KRAUSE T W, CLAPHAM L, PATTANTYUS A, Et al., Investigation of the stress-dependent magnetic easy axis in steel using magnetic Barkhausen noise, Journal of Applied Physics, 79, 8, (1996)

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